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|
-----------------------------------------------------------------------------
--
-- (c) The University of Glasgow, 2004-2006
--
-- Parser for concrete Cmm.
-- This doesn't just parse the Cmm file, we also do some code generation
-- along the way for switches and foreign calls etc.
--
-----------------------------------------------------------------------------
-- TODO: Add support for interruptible/uninterruptible foreign call specification
{
{-# LANGUAGE BangPatterns #-} -- required for versions of Happy before 1.18.6
{-# OPTIONS -Wwarn -w #-}
-- The above warning supression flag is a temporary kludge.
-- While working on this module you are encouraged to remove it and fix
-- any warnings in the module. See
-- http://hackage.haskell.org/trac/ghc/wiki/Commentary/CodingStyle#Warnings
-- for details
module CmmParse ( parseCmmFile ) where
import CgMonad hiding (getDynFlags)
import CgExtCode
import CgHeapery
import CgUtils
import CgProf
import CgTicky
import CgInfoTbls
import CgForeignCall
import CgTailCall
import CgStackery
import ClosureInfo
import CgCallConv
import CgClosure
import CostCentre
import BlockId
import OldCmm
import OldPprCmm()
import CmmUtils
import CmmLex
import CLabel
import SMRep
import Lexer
import ForeignCall
import Module
import Literal
import Unique
import UniqFM
import SrcLoc
import DynFlags
import StaticFlags
import ErrUtils
import StringBuffer
import FastString
import Panic
import Constants
import Outputable
import BasicTypes
import Bag ( emptyBag, unitBag )
import Var
import Control.Monad
import Data.Array
import Data.Char ( ord )
import System.Exit
#include "HsVersions.h"
}
%expect 0
%token
':' { L _ (CmmT_SpecChar ':') }
';' { L _ (CmmT_SpecChar ';') }
'{' { L _ (CmmT_SpecChar '{') }
'}' { L _ (CmmT_SpecChar '}') }
'[' { L _ (CmmT_SpecChar '[') }
']' { L _ (CmmT_SpecChar ']') }
'(' { L _ (CmmT_SpecChar '(') }
')' { L _ (CmmT_SpecChar ')') }
'=' { L _ (CmmT_SpecChar '=') }
'`' { L _ (CmmT_SpecChar '`') }
'~' { L _ (CmmT_SpecChar '~') }
'/' { L _ (CmmT_SpecChar '/') }
'*' { L _ (CmmT_SpecChar '*') }
'%' { L _ (CmmT_SpecChar '%') }
'-' { L _ (CmmT_SpecChar '-') }
'+' { L _ (CmmT_SpecChar '+') }
'&' { L _ (CmmT_SpecChar '&') }
'^' { L _ (CmmT_SpecChar '^') }
'|' { L _ (CmmT_SpecChar '|') }
'>' { L _ (CmmT_SpecChar '>') }
'<' { L _ (CmmT_SpecChar '<') }
',' { L _ (CmmT_SpecChar ',') }
'!' { L _ (CmmT_SpecChar '!') }
'..' { L _ (CmmT_DotDot) }
'::' { L _ (CmmT_DoubleColon) }
'>>' { L _ (CmmT_Shr) }
'<<' { L _ (CmmT_Shl) }
'>=' { L _ (CmmT_Ge) }
'<=' { L _ (CmmT_Le) }
'==' { L _ (CmmT_Eq) }
'!=' { L _ (CmmT_Ne) }
'&&' { L _ (CmmT_BoolAnd) }
'||' { L _ (CmmT_BoolOr) }
'CLOSURE' { L _ (CmmT_CLOSURE) }
'INFO_TABLE' { L _ (CmmT_INFO_TABLE) }
'INFO_TABLE_RET'{ L _ (CmmT_INFO_TABLE_RET) }
'INFO_TABLE_FUN'{ L _ (CmmT_INFO_TABLE_FUN) }
'INFO_TABLE_CONSTR'{ L _ (CmmT_INFO_TABLE_CONSTR) }
'INFO_TABLE_SELECTOR'{ L _ (CmmT_INFO_TABLE_SELECTOR) }
'else' { L _ (CmmT_else) }
'export' { L _ (CmmT_export) }
'section' { L _ (CmmT_section) }
'align' { L _ (CmmT_align) }
'goto' { L _ (CmmT_goto) }
'if' { L _ (CmmT_if) }
'jump' { L _ (CmmT_jump) }
'foreign' { L _ (CmmT_foreign) }
'never' { L _ (CmmT_never) }
'prim' { L _ (CmmT_prim) }
'return' { L _ (CmmT_return) }
'returns' { L _ (CmmT_returns) }
'import' { L _ (CmmT_import) }
'switch' { L _ (CmmT_switch) }
'case' { L _ (CmmT_case) }
'default' { L _ (CmmT_default) }
'bits8' { L _ (CmmT_bits8) }
'bits16' { L _ (CmmT_bits16) }
'bits32' { L _ (CmmT_bits32) }
'bits64' { L _ (CmmT_bits64) }
'float32' { L _ (CmmT_float32) }
'float64' { L _ (CmmT_float64) }
'gcptr' { L _ (CmmT_gcptr) }
GLOBALREG { L _ (CmmT_GlobalReg $$) }
NAME { L _ (CmmT_Name $$) }
STRING { L _ (CmmT_String $$) }
INT { L _ (CmmT_Int $$) }
FLOAT { L _ (CmmT_Float $$) }
%monad { P } { >>= } { return }
%lexer { cmmlex } { L _ CmmT_EOF }
%name cmmParse cmm
%tokentype { Located CmmToken }
-- C-- operator precedences, taken from the C-- spec
%right '||' -- non-std extension, called %disjoin in C--
%right '&&' -- non-std extension, called %conjoin in C--
%right '!'
%nonassoc '>=' '>' '<=' '<' '!=' '=='
%left '|'
%left '^'
%left '&'
%left '>>' '<<'
%left '-' '+'
%left '/' '*' '%'
%right '~'
%%
cmm :: { ExtCode }
: {- empty -} { return () }
| cmmtop cmm { do $1; $2 }
cmmtop :: { ExtCode }
: cmmproc { $1 }
| cmmdata { $1 }
| decl { $1 }
| 'CLOSURE' '(' NAME ',' NAME lits ')' ';'
{% withThisPackage $ \pkg ->
do lits <- sequence $6;
staticClosure pkg $3 $5 (map getLit lits) }
-- The only static closures in the RTS are dummy closures like
-- stg_END_TSO_QUEUE_closure and stg_dummy_ret. We don't need
-- to provide the full generality of static closures here.
-- In particular:
-- * CCS can always be CCS_DONT_CARE
-- * closure is always extern
-- * payload is always empty
-- * we can derive closure and info table labels from a single NAME
cmmdata :: { ExtCode }
: 'section' STRING '{' data_label statics '}'
{ do lbl <- $4;
ss <- sequence $5;
code (emitData (section $2) (Statics lbl $ concat ss)) }
data_label :: { ExtFCode CLabel }
: NAME ':'
{% withThisPackage $ \pkg ->
return (mkCmmDataLabel pkg $1) }
statics :: { [ExtFCode [CmmStatic]] }
: {- empty -} { [] }
| static statics { $1 : $2 }
-- Strings aren't used much in the RTS HC code, so it doesn't seem
-- worth allowing inline strings. C-- doesn't allow them anyway.
static :: { ExtFCode [CmmStatic] }
: type expr ';' { do e <- $2;
return [CmmStaticLit (getLit e)] }
| type ';' { return [CmmUninitialised
(widthInBytes (typeWidth $1))] }
| 'bits8' '[' ']' STRING ';' { return [mkString $4] }
| 'bits8' '[' INT ']' ';' { return [CmmUninitialised
(fromIntegral $3)] }
| typenot8 '[' INT ']' ';' { return [CmmUninitialised
(widthInBytes (typeWidth $1) *
fromIntegral $3)] }
| 'CLOSURE' '(' NAME lits ')'
{ do lits <- sequence $4;
return $ map CmmStaticLit $
mkStaticClosure (mkForeignLabel $3 Nothing ForeignLabelInExternalPackage IsData)
-- mkForeignLabel because these are only used
-- for CHARLIKE and INTLIKE closures in the RTS.
dontCareCCS (map getLit lits) [] [] [] }
-- arrays of closures required for the CHARLIKE & INTLIKE arrays
lits :: { [ExtFCode CmmExpr] }
: {- empty -} { [] }
| ',' expr lits { $2 : $3 }
cmmproc :: { ExtCode }
-- TODO: add real SRT/info tables to parsed Cmm
: info maybe_formals_without_hints maybe_gc_block maybe_frame '{' body '}'
{ do ((entry_ret_label, info, live, formals, gc_block, frame), stmts) <-
getCgStmtsEC' $ loopDecls $ do {
(entry_ret_label, info, live) <- $1;
formals <- sequence $2;
gc_block <- $3;
frame <- $4;
$6;
return (entry_ret_label, info, live, formals, gc_block, frame) }
blks <- code (cgStmtsToBlocks stmts)
code (emitInfoTableAndCode entry_ret_label (CmmInfo gc_block frame info) formals blks) }
| info maybe_formals_without_hints ';'
{ do (entry_ret_label, info, live) <- $1;
formals <- sequence $2;
code (emitInfoTableAndCode entry_ret_label (CmmInfo Nothing Nothing info) formals []) }
| NAME maybe_formals_without_hints maybe_gc_block maybe_frame '{' body '}'
{% withThisPackage $ \pkg ->
do newFunctionName $1 pkg
((formals, gc_block, frame), stmts) <-
getCgStmtsEC' $ loopDecls $ do {
formals <- sequence $2;
gc_block <- $3;
frame <- $4;
$6;
return (formals, gc_block, frame) }
blks <- code (cgStmtsToBlocks stmts)
code (emitProc (CmmInfo gc_block frame CmmNonInfoTable) (mkCmmCodeLabel pkg $1) formals blks) }
info :: { ExtFCode (CLabel, CmmInfoTable, [Maybe LocalReg]) }
: 'INFO_TABLE' '(' NAME ',' INT ',' INT ',' INT ',' STRING ',' STRING ')'
-- ptrs, nptrs, closure type, description, type
{% withThisPackage $ \pkg ->
do prof <- profilingInfo $11 $13
return (mkCmmEntryLabel pkg $3,
CmmInfoTable (mkCmmInfoLabel pkg $3) False prof (fromIntegral $9)
(ThunkInfo (fromIntegral $5, fromIntegral $7) NoC_SRT),
[]) }
| 'INFO_TABLE_FUN' '(' NAME ',' INT ',' INT ',' INT ',' STRING ',' STRING ',' INT ')'
-- ptrs, nptrs, closure type, description, type, fun type
{% withThisPackage $ \pkg ->
do prof <- profilingInfo $11 $13
return (mkCmmEntryLabel pkg $3,
CmmInfoTable (mkCmmInfoLabel pkg $3) False prof (fromIntegral $9)
(FunInfo (fromIntegral $5, fromIntegral $7) NoC_SRT
0 -- Arity zero
(ArgSpec (fromIntegral $15))
zeroCLit),
[]) }
-- we leave most of the fields zero here. This is only used
-- to generate the BCO info table in the RTS at the moment.
-- A variant with a non-zero arity (needed to write Main_main in Cmm)
| 'INFO_TABLE_FUN' '(' NAME ',' INT ',' INT ',' INT ',' STRING ',' STRING ',' INT ',' INT ')'
-- ptrs, nptrs, closure type, description, type, fun type, arity
{% withThisPackage $ \pkg ->
do prof <- profilingInfo $11 $13
return (mkCmmEntryLabel pkg $3,
CmmInfoTable (mkCmmInfoLabel pkg $3) False prof (fromIntegral $9)
(FunInfo (fromIntegral $5, fromIntegral $7) NoC_SRT (fromIntegral $17)
(ArgSpec (fromIntegral $15))
zeroCLit),
[]) }
-- we leave most of the fields zero here. This is only used
-- to generate the BCO info table in the RTS at the moment.
| 'INFO_TABLE_CONSTR' '(' NAME ',' INT ',' INT ',' INT ',' INT ',' STRING ',' STRING ')'
-- ptrs, nptrs, tag, closure type, description, type
{% withThisPackage $ \pkg ->
do prof <- profilingInfo $13 $15
-- If profiling is on, this string gets duplicated,
-- but that's the way the old code did it we can fix it some other time.
desc_lit <- code $ mkStringCLit $13
return (mkCmmEntryLabel pkg $3,
CmmInfoTable (mkCmmInfoLabel pkg $3) False prof (fromIntegral $11)
(ConstrInfo (fromIntegral $5, fromIntegral $7) (fromIntegral $9) desc_lit),
[]) }
| 'INFO_TABLE_SELECTOR' '(' NAME ',' INT ',' INT ',' STRING ',' STRING ')'
-- selector, closure type, description, type
{% withThisPackage $ \pkg ->
do prof <- profilingInfo $9 $11
return (mkCmmEntryLabel pkg $3,
CmmInfoTable (mkCmmInfoLabel pkg $3) False prof (fromIntegral $7)
(ThunkSelectorInfo (fromIntegral $5) NoC_SRT),
[]) }
| 'INFO_TABLE_RET' '(' NAME ',' INT ')'
-- closure type (no live regs)
{% withThisPackage $ \pkg ->
do let infoLabel = mkCmmInfoLabel pkg $3
return (mkCmmRetLabel pkg $3,
CmmInfoTable (mkCmmInfoLabel pkg $3) False (ProfilingInfo zeroCLit zeroCLit) (fromIntegral $5)
(ContInfo [] NoC_SRT),
[]) }
| 'INFO_TABLE_RET' '(' NAME ',' INT ',' formals_without_hints0 ')'
-- closure type, live regs
{% withThisPackage $ \pkg ->
do live <- sequence (map (liftM Just) $7)
return (mkCmmRetLabel pkg $3,
CmmInfoTable (mkCmmInfoLabel pkg $3) False (ProfilingInfo zeroCLit zeroCLit) (fromIntegral $5)
(ContInfo live NoC_SRT),
live) }
body :: { ExtCode }
: {- empty -} { return () }
| decl body { do $1; $2 }
| stmt body { do $1; $2 }
decl :: { ExtCode }
: type names ';' { mapM_ (newLocal $1) $2 }
| 'import' importNames ';' { mapM_ newImport $2 }
| 'export' names ';' { return () } -- ignore exports
-- an imported function name, with optional packageId
importNames
:: { [(FastString, CLabel)] }
: importName { [$1] }
| importName ',' importNames { $1 : $3 }
importName
:: { (FastString, CLabel) }
-- A label imported without an explicit packageId.
-- These are taken to come frome some foreign, unnamed package.
: NAME
{ ($1, mkForeignLabel $1 Nothing ForeignLabelInExternalPackage IsFunction) }
-- A label imported with an explicit packageId.
| STRING NAME
{ ($2, mkCmmCodeLabel (fsToPackageId (mkFastString $1)) $2) }
names :: { [FastString] }
: NAME { [$1] }
| NAME ',' names { $1 : $3 }
stmt :: { ExtCode }
: ';' { nopEC }
| NAME ':'
{ do l <- newLabel $1; code (labelC l) }
| lreg '=' expr ';'
{ do reg <- $1; e <- $3; stmtEC (CmmAssign reg e) }
| type '[' expr ']' '=' expr ';'
{ doStore $1 $3 $6 }
-- Gah! We really want to say "maybe_results" but that causes
-- a shift/reduce conflict with assignment. We either
-- we expand out the no-result and single result cases or
-- we tweak the syntax to avoid the conflict. The later
-- option is taken here because the other way would require
-- multiple levels of expanding and get unwieldy.
| maybe_results 'foreign' STRING expr '(' cmm_hint_exprs0 ')' safety vols opt_never_returns ';'
{% foreignCall $3 $1 $4 $6 $9 $8 $10 }
| maybe_results 'prim' '%' NAME '(' cmm_hint_exprs0 ')' safety vols ';'
{% primCall $1 $4 $6 $9 $8 }
-- stmt-level macros, stealing syntax from ordinary C-- function calls.
-- Perhaps we ought to use the %%-form?
| NAME '(' exprs0 ')' ';'
{% stmtMacro $1 $3 }
| 'switch' maybe_range expr '{' arms default '}'
{ do as <- sequence $5; doSwitch $2 $3 as $6 }
| 'goto' NAME ';'
{ do l <- lookupLabel $2; stmtEC (CmmBranch l) }
| 'jump' expr maybe_actuals ';'
{ do e1 <- $2; e2 <- sequence $3; stmtEC (CmmJump e1 e2) }
| 'return' maybe_actuals ';'
{ do e <- sequence $2; stmtEC (CmmReturn e) }
| 'if' bool_expr 'goto' NAME
{ do l <- lookupLabel $4; cmmRawIf $2 l }
| 'if' bool_expr '{' body '}' else
{ cmmIfThenElse $2 $4 $6 }
opt_never_returns :: { CmmReturnInfo }
: { CmmMayReturn }
| 'never' 'returns' { CmmNeverReturns }
bool_expr :: { ExtFCode BoolExpr }
: bool_op { $1 }
| expr { do e <- $1; return (BoolTest e) }
bool_op :: { ExtFCode BoolExpr }
: bool_expr '&&' bool_expr { do e1 <- $1; e2 <- $3;
return (BoolAnd e1 e2) }
| bool_expr '||' bool_expr { do e1 <- $1; e2 <- $3;
return (BoolOr e1 e2) }
| '!' bool_expr { do e <- $2; return (BoolNot e) }
| '(' bool_op ')' { $2 }
-- This is not C-- syntax. What to do?
safety :: { CmmSafety }
: {- empty -} { CmmUnsafe } -- Default may change soon
| STRING {% parseSafety $1 }
-- This is not C-- syntax. What to do?
vols :: { Maybe [GlobalReg] }
: {- empty -} { Nothing }
| '[' ']' { Just [] }
| '[' globals ']' { Just $2 }
globals :: { [GlobalReg] }
: GLOBALREG { [$1] }
| GLOBALREG ',' globals { $1 : $3 }
maybe_range :: { Maybe (Int,Int) }
: '[' INT '..' INT ']' { Just (fromIntegral $2, fromIntegral $4) }
| {- empty -} { Nothing }
arms :: { [ExtFCode ([Int],Either BlockId ExtCode)] }
: {- empty -} { [] }
| arm arms { $1 : $2 }
arm :: { ExtFCode ([Int],Either BlockId ExtCode) }
: 'case' ints ':' arm_body { do b <- $4; return ($2, b) }
arm_body :: { ExtFCode (Either BlockId ExtCode) }
: '{' body '}' { return (Right $2) }
| 'goto' NAME ';' { do l <- lookupLabel $2; return (Left l) }
ints :: { [Int] }
: INT { [ fromIntegral $1 ] }
| INT ',' ints { fromIntegral $1 : $3 }
default :: { Maybe ExtCode }
: 'default' ':' '{' body '}' { Just $4 }
-- taking a few liberties with the C-- syntax here; C-- doesn't have
-- 'default' branches
| {- empty -} { Nothing }
-- Note: OldCmm doesn't support a first class 'else' statement, though
-- CmmNode does.
else :: { ExtCode }
: {- empty -} { nopEC }
| 'else' '{' body '}' { $3 }
-- we have to write this out longhand so that Happy's precedence rules
-- can kick in.
expr :: { ExtFCode CmmExpr }
: expr '/' expr { mkMachOp MO_U_Quot [$1,$3] }
| expr '*' expr { mkMachOp MO_Mul [$1,$3] }
| expr '%' expr { mkMachOp MO_U_Rem [$1,$3] }
| expr '-' expr { mkMachOp MO_Sub [$1,$3] }
| expr '+' expr { mkMachOp MO_Add [$1,$3] }
| expr '>>' expr { mkMachOp MO_U_Shr [$1,$3] }
| expr '<<' expr { mkMachOp MO_Shl [$1,$3] }
| expr '&' expr { mkMachOp MO_And [$1,$3] }
| expr '^' expr { mkMachOp MO_Xor [$1,$3] }
| expr '|' expr { mkMachOp MO_Or [$1,$3] }
| expr '>=' expr { mkMachOp MO_U_Ge [$1,$3] }
| expr '>' expr { mkMachOp MO_U_Gt [$1,$3] }
| expr '<=' expr { mkMachOp MO_U_Le [$1,$3] }
| expr '<' expr { mkMachOp MO_U_Lt [$1,$3] }
| expr '!=' expr { mkMachOp MO_Ne [$1,$3] }
| expr '==' expr { mkMachOp MO_Eq [$1,$3] }
| '~' expr { mkMachOp MO_Not [$2] }
| '-' expr { mkMachOp MO_S_Neg [$2] }
| expr0 '`' NAME '`' expr0 {% do { mo <- nameToMachOp $3 ;
return (mkMachOp mo [$1,$5]) } }
| expr0 { $1 }
expr0 :: { ExtFCode CmmExpr }
: INT maybe_ty { return (CmmLit (CmmInt $1 (typeWidth $2))) }
| FLOAT maybe_ty { return (CmmLit (CmmFloat $1 (typeWidth $2))) }
| STRING { do s <- code (mkStringCLit $1);
return (CmmLit s) }
| reg { $1 }
| type '[' expr ']' { do e <- $3; return (CmmLoad e $1) }
| '%' NAME '(' exprs0 ')' {% exprOp $2 $4 }
| '(' expr ')' { $2 }
-- leaving out the type of a literal gives you the native word size in C--
maybe_ty :: { CmmType }
: {- empty -} { bWord }
| '::' type { $2 }
maybe_actuals :: { [ExtFCode HintedCmmActual] }
: {- empty -} { [] }
| '(' cmm_hint_exprs0 ')' { $2 }
cmm_hint_exprs0 :: { [ExtFCode HintedCmmActual] }
: {- empty -} { [] }
| cmm_hint_exprs { $1 }
cmm_hint_exprs :: { [ExtFCode HintedCmmActual] }
: cmm_hint_expr { [$1] }
| cmm_hint_expr ',' cmm_hint_exprs { $1 : $3 }
cmm_hint_expr :: { ExtFCode HintedCmmActual }
: expr { do e <- $1; return (CmmHinted e (inferCmmHint e)) }
| expr STRING {% do h <- parseCmmHint $2;
return $ do
e <- $1; return (CmmHinted e h) }
exprs0 :: { [ExtFCode CmmExpr] }
: {- empty -} { [] }
| exprs { $1 }
exprs :: { [ExtFCode CmmExpr] }
: expr { [ $1 ] }
| expr ',' exprs { $1 : $3 }
reg :: { ExtFCode CmmExpr }
: NAME { lookupName $1 }
| GLOBALREG { return (CmmReg (CmmGlobal $1)) }
maybe_results :: { [ExtFCode HintedCmmFormal] }
: {- empty -} { [] }
| '(' cmm_formals ')' '=' { $2 }
cmm_formals :: { [ExtFCode HintedCmmFormal] }
: cmm_formal { [$1] }
| cmm_formal ',' { [$1] }
| cmm_formal ',' cmm_formals { $1 : $3 }
cmm_formal :: { ExtFCode HintedCmmFormal }
: local_lreg { do e <- $1; return (CmmHinted e (inferCmmHint (CmmReg (CmmLocal e)))) }
| STRING local_lreg {% do h <- parseCmmHint $1;
return $ do
e <- $2; return (CmmHinted e h) }
local_lreg :: { ExtFCode LocalReg }
: NAME { do e <- lookupName $1;
return $
case e of
CmmReg (CmmLocal r) -> r
other -> pprPanic "CmmParse:" (ftext $1 <> text " not a local register") }
lreg :: { ExtFCode CmmReg }
: NAME { do e <- lookupName $1;
return $
case e of
CmmReg r -> r
other -> pprPanic "CmmParse:" (ftext $1 <> text " not a register") }
| GLOBALREG { return (CmmGlobal $1) }
maybe_formals_without_hints :: { [ExtFCode LocalReg] }
: {- empty -} { [] }
| '(' formals_without_hints0 ')' { $2 }
formals_without_hints0 :: { [ExtFCode LocalReg] }
: {- empty -} { [] }
| formals_without_hints { $1 }
formals_without_hints :: { [ExtFCode LocalReg] }
: formal_without_hint ',' { [$1] }
| formal_without_hint { [$1] }
| formal_without_hint ',' formals_without_hints { $1 : $3 }
formal_without_hint :: { ExtFCode LocalReg }
: type NAME { newLocal $1 $2 }
maybe_frame :: { ExtFCode (Maybe UpdateFrame) }
: {- empty -} { return Nothing }
| 'jump' expr '(' exprs0 ')' { do { target <- $2;
args <- sequence $4;
return $ Just (UpdateFrame target args) } }
maybe_gc_block :: { ExtFCode (Maybe BlockId) }
: {- empty -} { return Nothing }
| 'goto' NAME
{ do l <- lookupLabel $2; return (Just l) }
type :: { CmmType }
: 'bits8' { b8 }
| typenot8 { $1 }
typenot8 :: { CmmType }
: 'bits16' { b16 }
| 'bits32' { b32 }
| 'bits64' { b64 }
| 'float32' { f32 }
| 'float64' { f64 }
| 'gcptr' { gcWord }
{
section :: String -> Section
section "text" = Text
section "data" = Data
section "rodata" = ReadOnlyData
section "relrodata" = RelocatableReadOnlyData
section "bss" = UninitialisedData
section s = OtherSection s
mkString :: String -> CmmStatic
mkString s = CmmString (map (fromIntegral.ord) s)
-- mkMachOp infers the type of the MachOp from the type of its first
-- argument. We assume that this is correct: for MachOps that don't have
-- symmetrical args (e.g. shift ops), the first arg determines the type of
-- the op.
mkMachOp :: (Width -> MachOp) -> [ExtFCode CmmExpr] -> ExtFCode CmmExpr
mkMachOp fn args = do
arg_exprs <- sequence args
return (CmmMachOp (fn (typeWidth (cmmExprType (head arg_exprs)))) arg_exprs)
getLit :: CmmExpr -> CmmLit
getLit (CmmLit l) = l
getLit (CmmMachOp (MO_S_Neg _) [CmmLit (CmmInt i r)]) = CmmInt (negate i) r
getLit _ = panic "invalid literal" -- TODO messy failure
nameToMachOp :: FastString -> P (Width -> MachOp)
nameToMachOp name =
case lookupUFM machOps name of
Nothing -> fail ("unknown primitive " ++ unpackFS name)
Just m -> return m
exprOp :: FastString -> [ExtFCode CmmExpr] -> P (ExtFCode CmmExpr)
exprOp name args_code =
case lookupUFM exprMacros name of
Just f -> return $ do
args <- sequence args_code
return (f args)
Nothing -> do
mo <- nameToMachOp name
return $ mkMachOp mo args_code
exprMacros :: UniqFM ([CmmExpr] -> CmmExpr)
exprMacros = listToUFM [
( fsLit "ENTRY_CODE", \ [x] -> entryCode x ),
( fsLit "INFO_PTR", \ [x] -> closureInfoPtr x ),
( fsLit "STD_INFO", \ [x] -> infoTable x ),
( fsLit "FUN_INFO", \ [x] -> funInfoTable x ),
( fsLit "GET_ENTRY", \ [x] -> entryCode (closureInfoPtr x) ),
( fsLit "GET_STD_INFO", \ [x] -> infoTable (closureInfoPtr x) ),
( fsLit "GET_FUN_INFO", \ [x] -> funInfoTable (closureInfoPtr x) ),
( fsLit "INFO_TYPE", \ [x] -> infoTableClosureType x ),
( fsLit "INFO_PTRS", \ [x] -> infoTablePtrs x ),
( fsLit "INFO_NPTRS", \ [x] -> infoTableNonPtrs x )
]
-- we understand a subset of C-- primitives:
machOps = listToUFM $
map (\(x, y) -> (mkFastString x, y)) [
( "add", MO_Add ),
( "sub", MO_Sub ),
( "eq", MO_Eq ),
( "ne", MO_Ne ),
( "mul", MO_Mul ),
( "neg", MO_S_Neg ),
( "quot", MO_S_Quot ),
( "rem", MO_S_Rem ),
( "divu", MO_U_Quot ),
( "modu", MO_U_Rem ),
( "ge", MO_S_Ge ),
( "le", MO_S_Le ),
( "gt", MO_S_Gt ),
( "lt", MO_S_Lt ),
( "geu", MO_U_Ge ),
( "leu", MO_U_Le ),
( "gtu", MO_U_Gt ),
( "ltu", MO_U_Lt ),
( "and", MO_And ),
( "or", MO_Or ),
( "xor", MO_Xor ),
( "com", MO_Not ),
( "shl", MO_Shl ),
( "shrl", MO_U_Shr ),
( "shra", MO_S_Shr ),
( "fadd", MO_F_Add ),
( "fsub", MO_F_Sub ),
( "fneg", MO_F_Neg ),
( "fmul", MO_F_Mul ),
( "fquot", MO_F_Quot ),
( "feq", MO_F_Eq ),
( "fne", MO_F_Ne ),
( "fge", MO_F_Ge ),
( "fle", MO_F_Le ),
( "fgt", MO_F_Gt ),
( "flt", MO_F_Lt ),
( "lobits8", flip MO_UU_Conv W8 ),
( "lobits16", flip MO_UU_Conv W16 ),
( "lobits32", flip MO_UU_Conv W32 ),
( "lobits64", flip MO_UU_Conv W64 ),
( "zx16", flip MO_UU_Conv W16 ),
( "zx32", flip MO_UU_Conv W32 ),
( "zx64", flip MO_UU_Conv W64 ),
( "sx16", flip MO_SS_Conv W16 ),
( "sx32", flip MO_SS_Conv W32 ),
( "sx64", flip MO_SS_Conv W64 ),
( "f2f32", flip MO_FF_Conv W32 ), -- TODO; rounding mode
( "f2f64", flip MO_FF_Conv W64 ), -- TODO; rounding mode
( "f2i8", flip MO_FS_Conv W8 ),
( "f2i16", flip MO_FS_Conv W16 ),
( "f2i32", flip MO_FS_Conv W32 ),
( "f2i64", flip MO_FS_Conv W64 ),
( "i2f32", flip MO_SF_Conv W32 ),
( "i2f64", flip MO_SF_Conv W64 )
]
callishMachOps = listToUFM $
map (\(x, y) -> (mkFastString x, y)) [
( "write_barrier", MO_WriteBarrier ),
( "memcpy", MO_Memcpy ),
( "memset", MO_Memset ),
( "memmove", MO_Memmove )
-- ToDo: the rest, maybe
]
parseSafety :: String -> P CmmSafety
parseSafety "safe" = return (CmmSafe NoC_SRT)
parseSafety "unsafe" = return CmmUnsafe
parseSafety "interruptible" = return CmmInterruptible
parseSafety str = fail ("unrecognised safety: " ++ str)
parseCmmHint :: String -> P ForeignHint
parseCmmHint "ptr" = return AddrHint
parseCmmHint "signed" = return SignedHint
parseCmmHint str = fail ("unrecognised hint: " ++ str)
-- labels are always pointers, so we might as well infer the hint
inferCmmHint :: CmmExpr -> ForeignHint
inferCmmHint (CmmLit (CmmLabel _)) = AddrHint
inferCmmHint (CmmReg (CmmGlobal g)) | isPtrGlobalReg g = AddrHint
inferCmmHint _ = NoHint
isPtrGlobalReg Sp = True
isPtrGlobalReg SpLim = True
isPtrGlobalReg Hp = True
isPtrGlobalReg HpLim = True
isPtrGlobalReg CurrentTSO = True
isPtrGlobalReg CurrentNursery = True
isPtrGlobalReg (VanillaReg _ VGcPtr) = True
isPtrGlobalReg _ = False
happyError :: P a
happyError = srcParseFail
-- -----------------------------------------------------------------------------
-- Statement-level macros
stmtMacro :: FastString -> [ExtFCode CmmExpr] -> P ExtCode
stmtMacro fun args_code = do
case lookupUFM stmtMacros fun of
Nothing -> fail ("unknown macro: " ++ unpackFS fun)
Just fcode -> return $ do
args <- sequence args_code
code (fcode args)
stmtMacros :: UniqFM ([CmmExpr] -> Code)
stmtMacros = listToUFM [
( fsLit "CCS_ALLOC", \[words,ccs] -> profAlloc words ccs ),
( fsLit "CLOSE_NURSERY", \[] -> emitCloseNursery ),
( fsLit "ENTER_CCS_PAP_CL", \[e] -> enterCostCentrePAP e ),
( fsLit "ENTER_CCS_THUNK", \[e] -> enterCostCentreThunk e ),
( fsLit "HP_CHK_GEN", \[words,liveness,reentry] ->
hpChkGen words liveness reentry ),
( fsLit "HP_CHK_NP_ASSIGN_SP0", \[e,f] -> hpChkNodePointsAssignSp0 e f ),
( fsLit "LOAD_THREAD_STATE", \[] -> emitLoadThreadState ),
( fsLit "LDV_ENTER", \[e] -> ldvEnter e ),
( fsLit "LDV_RECORD_CREATE", \[e] -> ldvRecordCreate e ),
( fsLit "OPEN_NURSERY", \[] -> emitOpenNursery ),
( fsLit "PUSH_UPD_FRAME", \[sp,e] -> emitPushUpdateFrame sp e ),
( fsLit "SAVE_THREAD_STATE", \[] -> emitSaveThreadState ),
( fsLit "SET_HDR", \[ptr,info,ccs] ->
emitSetDynHdr ptr info ccs ),
( fsLit "STK_CHK_GEN", \[words,liveness,reentry] ->
stkChkGen words liveness reentry ),
( fsLit "STK_CHK_NP", \[e] -> stkChkNodePoints e ),
( fsLit "TICK_ALLOC_PRIM", \[hdr,goods,slop] ->
tickyAllocPrim hdr goods slop ),
( fsLit "TICK_ALLOC_PAP", \[goods,slop] ->
tickyAllocPAP goods slop ),
( fsLit "TICK_ALLOC_UP_THK", \[goods,slop] ->
tickyAllocThunk goods slop ),
( fsLit "UPD_BH_UPDATABLE", \[] -> emitBlackHoleCode False ),
( fsLit "UPD_BH_SINGLE_ENTRY", \[] -> emitBlackHoleCode True ),
( fsLit "RET_P", \[a] -> emitRetUT [(PtrArg,a)]),
( fsLit "RET_N", \[a] -> emitRetUT [(NonPtrArg,a)]),
( fsLit "RET_PP", \[a,b] -> emitRetUT [(PtrArg,a),(PtrArg,b)]),
( fsLit "RET_NN", \[a,b] -> emitRetUT [(NonPtrArg,a),(NonPtrArg,b)]),
( fsLit "RET_NP", \[a,b] -> emitRetUT [(NonPtrArg,a),(PtrArg,b)]),
( fsLit "RET_PPP", \[a,b,c] -> emitRetUT [(PtrArg,a),(PtrArg,b),(PtrArg,c)]),
( fsLit "RET_NPP", \[a,b,c] -> emitRetUT [(NonPtrArg,a),(PtrArg,b),(PtrArg,c)]),
( fsLit "RET_NNP", \[a,b,c] -> emitRetUT [(NonPtrArg,a),(NonPtrArg,b),(PtrArg,c)]),
( fsLit "RET_NNN", \[a,b,c] -> emitRetUT [(NonPtrArg,a),(NonPtrArg,b),(NonPtrArg,c)]),
( fsLit "RET_NNNN", \[a,b,c,d] -> emitRetUT [(NonPtrArg,a),(NonPtrArg,b),(NonPtrArg,c),(NonPtrArg,d)]),
( fsLit "RET_NNNP", \[a,b,c,d] -> emitRetUT [(NonPtrArg,a),(NonPtrArg,b),(NonPtrArg,c),(PtrArg,d)]),
( fsLit "RET_NPNP", \[a,b,c,d] -> emitRetUT [(NonPtrArg,a),(PtrArg,b),(NonPtrArg,c),(PtrArg,d)])
]
profilingInfo desc_str ty_str = do
lit1 <- if opt_SccProfilingOn
then code $ mkStringCLit desc_str
else return (mkIntCLit 0)
lit2 <- if opt_SccProfilingOn
then code $ mkStringCLit ty_str
else return (mkIntCLit 0)
return (ProfilingInfo lit1 lit2)
staticClosure :: PackageId -> FastString -> FastString -> [CmmLit] -> ExtCode
staticClosure pkg cl_label info payload
= code $ emitDataLits (mkCmmDataLabel pkg cl_label) lits
where lits = mkStaticClosure (mkCmmInfoLabel pkg info) dontCareCCS payload [] [] []
foreignCall
:: String
-> [ExtFCode HintedCmmFormal]
-> ExtFCode CmmExpr
-> [ExtFCode HintedCmmActual]
-> Maybe [GlobalReg]
-> CmmSafety
-> CmmReturnInfo
-> P ExtCode
foreignCall conv_string results_code expr_code args_code vols safety ret
= do convention <- case conv_string of
"C" -> return CCallConv
"stdcall" -> return StdCallConv
"C--" -> return CmmCallConv
_ -> fail ("unknown calling convention: " ++ conv_string)
return $ do
results <- sequence results_code
expr <- expr_code
args <- sequence args_code
--code (stmtC (CmmCall (CmmCallee expr convention) results args safety))
case convention of
-- Temporary hack so at least some functions are CmmSafe
CmmCallConv -> code (stmtC (CmmCall (CmmCallee expr convention) results args safety ret))
_ ->
let expr' = adjCallTarget convention expr args in
case safety of
CmmUnsafe ->
code (emitForeignCall' PlayRisky results
(CmmCallee expr' convention) args vols NoC_SRT ret)
CmmSafe srt ->
code (emitForeignCall' PlaySafe results
(CmmCallee expr' convention) args vols NoC_SRT ret) where
CmmInterruptible ->
code (emitForeignCall' PlayInterruptible results
(CmmCallee expr' convention) args vols NoC_SRT ret)
adjCallTarget :: CCallConv -> CmmExpr -> [CmmHinted CmmExpr] -> CmmExpr
#ifdef mingw32_TARGET_OS
-- On Windows, we have to add the '@N' suffix to the label when making
-- a call with the stdcall calling convention.
adjCallTarget StdCallConv (CmmLit (CmmLabel lbl)) args
= CmmLit (CmmLabel (addLabelSize lbl (sum (map size args))))
where size (CmmHinted e _) = max wORD_SIZE (widthInBytes (typeWidth (cmmExprType e)))
-- c.f. CgForeignCall.emitForeignCall
#endif
adjCallTarget _ expr _
= expr
primCall
:: [ExtFCode HintedCmmFormal]
-> FastString
-> [ExtFCode HintedCmmActual]
-> Maybe [GlobalReg]
-> CmmSafety
-> P ExtCode
primCall results_code name args_code vols safety
= case lookupUFM callishMachOps name of
Nothing -> fail ("unknown primitive " ++ unpackFS name)
Just p -> return $ do
results <- sequence results_code
args <- sequence args_code
case safety of
CmmUnsafe ->
code (emitForeignCall' PlayRisky results
(CmmPrim p) args vols NoC_SRT CmmMayReturn)
CmmSafe srt ->
code (emitForeignCall' PlaySafe results
(CmmPrim p) args vols NoC_SRT CmmMayReturn) where
CmmInterruptible ->
code (emitForeignCall' PlayInterruptible results
(CmmPrim p) args vols NoC_SRT CmmMayReturn)
doStore :: CmmType -> ExtFCode CmmExpr -> ExtFCode CmmExpr -> ExtCode
doStore rep addr_code val_code
= do addr <- addr_code
val <- val_code
-- if the specified store type does not match the type of the expr
-- on the rhs, then we insert a coercion that will cause the type
-- mismatch to be flagged by cmm-lint. If we don't do this, then
-- the store will happen at the wrong type, and the error will not
-- be noticed.
let val_width = typeWidth (cmmExprType val)
rep_width = typeWidth rep
let coerce_val
| val_width /= rep_width = CmmMachOp (MO_UU_Conv val_width rep_width) [val]
| otherwise = val
stmtEC (CmmStore addr coerce_val)
-- Return an unboxed tuple.
emitRetUT :: [(CgRep,CmmExpr)] -> Code
emitRetUT args = do
tickyUnboxedTupleReturn (length args) -- TICK
(sp, stmts) <- pushUnboxedTuple 0 args
emitSimultaneously stmts -- NB. the args might overlap with the stack slots
-- or regs that we assign to, so better use
-- simultaneous assignments here (#3546)
when (sp /= 0) $ stmtC (CmmAssign spReg (cmmRegOffW spReg (-sp)))
stmtC (CmmJump (entryCode (CmmLoad (cmmRegOffW spReg sp) bWord)) [])
-- TODO (when using CPS): emitStmt (CmmReturn (map snd args))
-- -----------------------------------------------------------------------------
-- If-then-else and boolean expressions
data BoolExpr
= BoolExpr `BoolAnd` BoolExpr
| BoolExpr `BoolOr` BoolExpr
| BoolNot BoolExpr
| BoolTest CmmExpr
-- ToDo: smart constructors which simplify the boolean expression.
cmmIfThenElse cond then_part else_part = do
then_id <- code newLabelC
join_id <- code newLabelC
c <- cond
emitCond c then_id
else_part
stmtEC (CmmBranch join_id)
code (labelC then_id)
then_part
-- fall through to join
code (labelC join_id)
cmmRawIf cond then_id = do
c <- cond
emitCond c then_id
-- 'emitCond cond true_id' emits code to test whether the cond is true,
-- branching to true_id if so, and falling through otherwise.
emitCond (BoolTest e) then_id = do
stmtEC (CmmCondBranch e then_id)
emitCond (BoolNot (BoolTest (CmmMachOp op args))) then_id
| Just op' <- maybeInvertComparison op
= emitCond (BoolTest (CmmMachOp op' args)) then_id
emitCond (BoolNot e) then_id = do
else_id <- code newLabelC
emitCond e else_id
stmtEC (CmmBranch then_id)
code (labelC else_id)
emitCond (e1 `BoolOr` e2) then_id = do
emitCond e1 then_id
emitCond e2 then_id
emitCond (e1 `BoolAnd` e2) then_id = do
-- we'd like to invert one of the conditionals here to avoid an
-- extra branch instruction, but we can't use maybeInvertComparison
-- here because we can't look too closely at the expression since
-- we're in a loop.
and_id <- code newLabelC
else_id <- code newLabelC
emitCond e1 and_id
stmtEC (CmmBranch else_id)
code (labelC and_id)
emitCond e2 then_id
code (labelC else_id)
-- -----------------------------------------------------------------------------
-- Table jumps
-- We use a simplified form of C-- switch statements for now. A
-- switch statement always compiles to a table jump. Each arm can
-- specify a list of values (not ranges), and there can be a single
-- default branch. The range of the table is given either by the
-- optional range on the switch (eg. switch [0..7] {...}), or by
-- the minimum/maximum values from the branches.
doSwitch :: Maybe (Int,Int) -> ExtFCode CmmExpr -> [([Int],Either BlockId ExtCode)]
-> Maybe ExtCode -> ExtCode
doSwitch mb_range scrut arms deflt
= do
-- Compile code for the default branch
dflt_entry <-
case deflt of
Nothing -> return Nothing
Just e -> do b <- forkLabelledCodeEC e; return (Just b)
-- Compile each case branch
table_entries <- mapM emitArm arms
-- Construct the table
let
all_entries = concat table_entries
ixs = map fst all_entries
(min,max)
| Just (l,u) <- mb_range = (l,u)
| otherwise = (minimum ixs, maximum ixs)
entries = elems (accumArray (\_ a -> Just a) dflt_entry (min,max)
all_entries)
expr <- scrut
-- ToDo: check for out of range and jump to default if necessary
stmtEC (CmmSwitch expr entries)
where
emitArm :: ([Int],Either BlockId ExtCode) -> ExtFCode [(Int,BlockId)]
emitArm (ints,Left blockid) = return [ (i,blockid) | i <- ints ]
emitArm (ints,Right code) = do
blockid <- forkLabelledCodeEC code
return [ (i,blockid) | i <- ints ]
-- -----------------------------------------------------------------------------
-- Putting it all together
-- The initial environment: we define some constants that the compiler
-- knows about here.
initEnv :: Env
initEnv = listToUFM [
( fsLit "SIZEOF_StgHeader",
Var (CmmLit (CmmInt (fromIntegral (fixedHdrSize * wORD_SIZE)) wordWidth) )),
( fsLit "SIZEOF_StgInfoTable",
Var (CmmLit (CmmInt (fromIntegral stdInfoTableSizeB) wordWidth) ))
]
parseCmmFile :: DynFlags -> FilePath -> IO (Messages, Maybe Cmm)
parseCmmFile dflags filename = do
showPass dflags "ParseCmm"
buf <- hGetStringBuffer filename
let
init_loc = mkRealSrcLoc (mkFastString filename) 1 1
init_state = (mkPState dflags buf init_loc) { lex_state = [0] }
-- reset the lex_state: the Lexer monad leaves some stuff
-- in there we don't want.
case unP cmmParse init_state of
PFailed span err -> do
let msg = mkPlainErrMsg span err
return ((emptyBag, unitBag msg), Nothing)
POk pst code -> do
cmm <- initC dflags no_module (getCmm (unEC code initEnv [] >> return ()))
let ms = getMessages pst
if (errorsFound dflags ms)
then return (ms, Nothing)
else do
dumpIfSet_dyn dflags Opt_D_dump_cmm "Cmm" (pprPlatform (targetPlatform dflags) cmm)
return (ms, Just cmm)
where
no_module = panic "parseCmmFile: no module"
}
|